Heatsink with adjustable fin pitch

ABSTRACT

An apparatus includes at least one heat pipe that is adapted to be thermally coupled to an integrated circuit and has an evaporator portion and a first condenser portion, wherein the first condenser portion extends away from the evaporator portion; a first plurality of cooling fins that is attached to the first condenser portion; a first movable support that is thermally coupled to the first condenser portion and is configured to move a second plurality of cooling fins relative to the first plurality of cooling fins; and the second plurality of cooling fins, which is attached to the first movable support.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of the co-pending U.S. Pat. Applicationtitled, “HEAT SINK WITH ADJUSTABLE FIN PITCH”, filed on Aug. 12, 2020,and having Serial No. 16/992,035, which claims the priority benefit ofU.S. Provisional Pat. Application titled, “HEATSINK WITH ADJUSTABLE FINPITCH”, filed Feb. 18, 2020, and having Serial No. 62/978,283. Thesubject matter of these related applications is hereby incorporatedherein by reference.

BACKGROUND Field of the Various Embodiments

The various embodiments relate generally to computer systems andcomputer architecture and, more specifically, to a heat sink withadjustable fin pitch.

Description of the Related Art

In modern computing systems, central processing units (CPUs), graphicsprocessing units (GPUs), and other integrated circuits (ICs) generatesignificant quantities of heat during use. This heat needs to be removedfor the proper operation of the integrated circuit and computing system.For example, a single high-power chip, such as a CPU or GPU, cangenerate hundreds of watts of heat during operation, and, if this heatis not efficiently removed, the temperature of the chip can increase toa point at which the chip is at risk of being damaged. To preventthermal damage during operation, many systems implement clock-speedthrottling when the operating temperature of the processor exceeds acertain threshold. Thus, in these systems, the processing speed of thehigh-power chip is constrained by both the chip design and howeffectively heat is removed from the chip.

To reduce the impact that thermal constraints have on high-power chipperformance, heat exchangers are often employed that allow high-powerchips to operate at greater processing speeds and generate greateramounts of heat. Heat exchangers are designed to efficiently transferheat from a chip to ambient air, and the air then carries the heat awayfrom the chip. Heat exchangers can include passive devices, such as heatsinks, or more complex heat-transfer devices, such as heat pipes. Heatsinks generally include an array of fins that increase the effectivesurface area of the chip exposed to ambient air, while heat pipes relyon phase transition (e.g., evaporation of a liquid) to efficientlytransfer heat between two solid interfaces. In some instances, heatpipes are used in conjunction with heat sinks to increase the amount ofheat that can be removed from a high-power chip.

To further facilitate the cooling of high-power chips, computing systemstypically also include one or more cooling fans that are arranged toeither push or pull air across the heat exchangers coupled to thehigh-power chips. Because cooling fans typically generate unidirectionalairflow inside a computer system, some high-power chips andheat-generating devices usually are disposed downstream of otherhigh-power chips or heat-generating devices in a given computing device.As cooling air passes over the upstream devices, those devices add heatto the cooling air, which results in the downstream devices being cooledby substantially warmer air than the upstream devices. Consequently, thedownstream devices tend to “run hotter” than the upstream devices, whichcan limit the processing speeds of the downstream devices.

One approach for addressing the above phenomenon is to couple lessefficient heat exchangers to the upstream devices within a computingdevices. For example, heat exchangers having fewer cooling fins could becoupled to the upstream devices within a given computing device. Withsuch an approach, less heat is added to the cooling air as the airpasses over the upstream devices, which results in more effectivecooling of the downstream devices when the cooling air passes over thedownstream devices.

One drawback to such an approach is that processor boards configured inthis way are compatible with a single direction of airflow, and haveoptimal performance when installed to receive airflow in that direction.Thus, the flexibility of the placement of such processor boards islimited. Further, for certain computer systems, e.g., cloud-computingservers, the direction of airflow through the computer system can varydepending on site-specific factors, such as the layout design of thecomputer system. Thus, when employed in a cloud-computing server, twoconfigurations of the same processor board may be manufactured, one forapplications in which cooling airflow passes through the computer systemin one direction and another for applications in which cooling airflowpasses through the computer system in the opposite direction.

As the foregoing illustrates, what is needed in the art is a moreeffective way to cool electronics devices within computer systems.

SUMMARY

An apparatus includes at least one heat pipe that is adapted to bethermally coupled to an integrated circuit and has an evaporator portionand a first condenser portion, wherein the first condenser portionextends away from the evaporator portion; a first plurality of coolingfins that is attached to the first condenser portion; a first movablesupport that is thermally coupled to the first condenser portion and isconfigured to move a second plurality of cooling fins relative to thefirst plurality of cooling fins; and the second plurality of coolingfins, which is attached to the first movable support.

At least one technical advantage of the disclosed approach relative tothe prior art is that the disclosed approach results in more efficientcooling of an electronic device that is disposed within a computersystem downstream of an adjustable heat sink. More specifically, whenthe adjustable heat sink is coupled to an upstream electronic devicewithin the computer system, the cooling efficiency of the adjustableheat sink can be reduced, causing the temperature of cooling air exitingthe adjustable heat sink to decrease. As that relatively cooler airpasses over a downstream electronic device within the computer system,the downstream device is cooled relatively more effectively. Thus, theadjustable heat sink can selectively modify the efficiency of cooling ofthe upstream electronic device relative to that of the downstreamelectronic device. Since the adjustable heat sink can be employed in acomputer system as both an upstream heat sink and as a downstream heatsink, the manufacturing process for the computer system is simplified.Further, in operation, the adjustable heat sink provides flexibility inthe placement or orientation within a computer system of a processorboard that includes upstream and downstream heat-generating electronicdevices. These technical advantages provide one or more technologicaladvancements over prior art approaches.

BRIEF DESCRIPTION OF THE DRAWINGS

So that the manner in which the above recited features of the variousembodiments can be understood in detail, a more particular descriptionof the inventive concepts, briefly summarized above, may be had byreference to various embodiments, some of which are illustrated in theappended drawings. It is to be noted, however, that the appendeddrawings illustrate only typical embodiments of the inventive conceptsand are therefore not to be considered limiting of scope in any way, andthat there are other equally effective embodiments.

FIG. 1 is a perspective view of a computer system configured toimplement one or more aspects of the various embodiments;

FIG. 2 is a perspective view of a heat exchanger that can be implementedin the computer system of FIG. 1 , according to various embodiments;

FIG. 3 is a perspective view of a movable support disposed within theheat exchanger of FIG. 2 , according to various embodiments;

FIG. 4A is an end view of the heat exchanger of FIG. 2 in an upstreamheat exchanger configuration, according to various embodiments;

FIG. 4B is an end view of the heat exchanger of FIG. 2 in a downstreamheat exchanger configuration, according to various embodiments;

FIGS. 5A - 5C illustrate various cooling fins included in the adjustableheat exchanger of FIG. 2 , according to various embodiments;

FIG. 6 is a perspective view of the heat exchanger of FIG. 2 whenpartially assembled, according to various embodiments;

FIG. 7 illustrates various cooling fins that are each included in adifferent group of adjustable cooling fins that can be implemented in anadjustable heat sink, according to various embodiments; and

FIG. 8 is a flowchart of method steps for controlling an adjustable heatsink, according to various embodiments.

For clarity, identical reference numbers have been used, whereapplicable, to designate identical elements that are common betweenfigures. It is contemplated that features of one embodiment may beincorporated in other embodiments without further recitation.

DETAILED DESCRIPTION

In the following description, numerous specific details are set forth toprovide a more thorough understanding of the various embodiments.However, it will be apparent to one of skilled in the art that theinventive concepts may be practiced without one or more of thesespecific details.

Computer System With Adjustable Heat Sink

FIG. 1 is a perspective view of a computer system 100, according tovarious embodiments. Computer system 100 is a computing device or aportion of a computing device, such as a server machine, personalcomputer, laptop, tablet, video game console, personal digitalassistant, mobile phone, mobile device or any other electronic devicesuitable for practicing the embodiments herein. In the embodimentillustrated in FIG. 1 , computer system 100 is depicted as a serverboard of a distributed-computing system or cloud-computing system thatincludes multiple integrated circuits (ICs) mounted on a single printedcircuit board (PCB) 102. As such, computer system 100 is configured tobe installed with a plurality of other server boards in, for example, aserver rack. However, FIG. 1 in no way limits or is intended to limitthe scope of the embodiments described herein, and computer system 100can be any other computing system that includes multiple ICs that areeach coupled to a respective heat exchanger 103. In such embodiments,some or all of the multiple ICs are coupled to a respective heatexchanger 103. In addition to the multiple ICs, which are not visible inFIG. 1 , computer system 100 can also include various other electroniccomponents 104 mounted on PCB 102. In the example of FIG. 1 , thedirection of airflow is from left to right, but in other embodiments,the direction of airflow may be in a different direction.

As shown, computer system 100 can include two or more rows of ICs andassociated heat exchangers 103. Further, in some embodiments, coolingair is directed by one or more fans (not shown) that either push or pullair in one direction across computer system 100 and heat exchangers 103.Thus, the flow of cooling air (or other cooling fluid) over computersystem 100 is unidirectional and flows sequentially through a first row120 of “upstream” heat exchangers 103A of computer system 100 and thenthrough a second row 130 of “downstream” heat exchangers 103B ofcomputer system 100. As a result, upstream heat exchangers 103A in firstrow 120 receive cooling air (or other cooling fluid) before downstreamheat exchangers 103B in second row 130 receive the cooling air (or othercooling fluid).

Since upstream heat exchangers 103A receive the airflow beforedownstream heat exchangers 103B, the temperature of the cooling airflowreceived by upstream heat exchangers 103A is typically lower than thetemperature of the cooling airflow received by downstream heatexchangers 103B. In general, heat transfer from a cooling fluid when ata lower temperature is more efficient than heat transfer from thecooling fluid when at a higher temperature. Thus, heat transfer fromdownstream heat exchangers 103B is generally more difficult than fromupstream heat exchangers 103A. For example, when upstream heatexchangers 103A and downstream heat exchangers 103B have identicalconfigurations, heat transfer generally occurs at a higher rate fromupstream heat exchangers 103A. As a result, the ICs cooled by downstreamheat exchangers 103B tend to operate at higher temperatures than the ICscooled by upstream heat exchangers 103A.

According to various embodiments, an adjustable heat sink that has anadjustable and/or variable fin pitch can be employed in computer system100 both upstream head exchangers 103A and downstream heat exchangers103B. Advantageously, a single adjustable heat sink can be manufacturedfor use in computer system 100 instead of a heat sink with an upstreamconfiguration and heat sink with a downstream configuration, whichreduces manufacturing costs and complexity. Further, in operation aftermanufacture, the fin pitch of the herein-described adjustable heat sinkcan be changed depending on whether the adjustable heat sink is used inan upstream heat exchanger or a downstream heat exchanger. Thus,flexibility in terms of the placement or orientation of computer system100 within a larger system is provided. One such embodiment isillustrated in FIG. 2 .

FIG. 2 is a perspective view of a heat exchanger 200 that can beimplemented in computer system 100, according to various embodiments.Heat exchanger 200 is a heat exchanger for an IC 201, and can beemployed in computer system 100 of FIG. 1 as one or more of upstreamheat exchangers 103A and as one or more of downstream heat exchangers103B. Heat exchanger 200 includes one or more heat pipes 240 anadjustable heat sink 220 with a plurality of cooling fins 221. In theembodiment illustrated in FIG. 2 , the one or more heat pipes 240 arethermally coupled to IC 201 and to cooling fins 221. Together, heatexchanger 200 and IC 201 form an electronic device that can be mountedon a PCB (not shown), such as PCB 102 in FIG. 1 .

In some embodiments, IC 201 includes a single microchip, such as agraphics processing unit (GPU) or central-processing unit (CPU).Alternatively, in some embodiments IC 201 includes multiple microchips,such as a processor die and one or more stacks of memory dies that areall mounted on a common packaging substrate. In such embodiments, thepackaging substrate can be configured for mounting IC onto a PCB (notshown), for example via solder balls (not shown). In addition, in suchembodiments, IC 201 may include a package lid, which protects theprocessor die and the one or more stacks of memory dies from physicaldamage, but also increases thermal resistance associated with thepackaging of IC 201. Further, in some multi-microchip embodiments, IC201 can include other configurations of chips, such as a system-on-chip(SoC) configuration.

Heat pipes 240 are sealed vessels, such as copper tubes, that include anevaporative working fluid (not shown), such as water or alcohol. Heatpipes 240 efficiently transfer heat, through a combination ofevaporation and condensation, from IC 201 to cooling fins 221 and on tocooling air (or any other cooling fluid) that passes over cooling fins221. More specifically, in heat pipes 240, evaporation of the workingfluid into a vapor takes place in an evaporator portion 241 of each heatpipe 240, while condensation of the working fluid takes place in one ormore condenser portions 242. Each evaporator portion 241 is coupled to asurface from which thermal energy is to be removed, and each condenserportion 242 extends away from the surface from which the thermal energyis to be removed. In the embodiment illustrated in FIG. 2 , each heatpipe 240 includes two condenser portions 242, but in other embodiments,each heat pipe 240 can include more than or fewer than two condenserportions 242. Condensed working fluid from condenser portions 242 flowsto a corresponding evaporator portion 241, where thermal energy from IC201 is absorbed and the working fluid vaporizes. The vapor then moves tocondenser portions 242 and condenses in the condenser portion 242,releasing latent heat. In some embodiments, each heat pipe 240 alsoincludes a wicking structure or material (not shown) on some or allinner surfaces, to facilitate the return of condensed cooling liquid tothe evaporator portion 241 of the heat pipe 240.

In the embodiment illustrated, heat pipes 240 are mounted on a metallicplate 250, such as a copper or aluminum plate, that is thermally coupledto IC 201. In such embodiments, metallic plate 250 can be thermallycoupled to a surface of IC 201 via a thermal interface material (TIM),for example a highly thermally conductive paste. In the embodimentillustrated in FIG. 2 , metallic plate 250 spreads heat over a surfacearea that is greater than that of IC 201. As a result, a larger numberof heat pipes 240 can be thermally coupled to IC 201 on metallic plate250 than when directly attached to IC 201.

Cooling fins 221 can be any material that conducts heat efficiently,such as copper or aluminum. Cooling fins 221 are oriented to allow acooling fluid (referred to herein as “cooling air”) to flow in either ofairflow directions 203 or 204 between cooling fins 221. The cooling airflowing between cooling fins 221 also flows across condenser portions242 of heat pipes 240.

According to various embodiments, cooling fins 221 include multiplegroups of cooling fins, where at least one group of cooling fins iscoupled to one or more of heat pipes 240 and at least one group ofcooling fins is coupled to a movable support 260. In the embodimentillustrated in FIG. 2 , a first group 231 of cooling fins 221 is coupledto condenser portions 242 of heat pipes 240 proximate to evaporatorportions 241, a third group 233 of cooling fins 221 is coupled tocondenser portions 242 of heat pipes 240 distal to evaporator portions241, and a second group 232 of cooling fins 221 is coupled to evaporatorportions 241 and is disposed between first group 231 and third group233. In addition, a fourth group 234 of cooling fins 221 is coupled tomovable support 260 and is disposed between first group 231 and thirdgroup 233. The cooling fins of first group 231, second group 232, andthird group 233 are fixed in position, i.e., stationary. By contrast,the cooling fins of fourth group 234 are adjustable, in that the coolingfins of fourth group 234 can be moved in a vertical direction 202 bymovable support 260.

The cooling fins of first group 231 are configured with a fixed finpitch 231A, the cooling fins of second group 232 are configured with afixed fin pitch 232A, the cooling fins of third group 233 are configuredwith a fixed fin pitch 233A, and the cooling fins of fourth group 234are configured with a fixed fin pitch 234A. In the embodimentillustrated in FIG. 2 , fixed fin pitch 232A and fixed fin pitch 234Aare equal and are greater than fixed fin pitch 231A and fixed fin pitch233A. In other embodiments, fixed fin pitch 231A and fixed fin pitch233A can be greater than fixed fin pitch 232A and fixed fin pitch 234A.

As shown, the cooling fins of fourth group 234 are interleaved betweenat least a portion of the stationary cooling fins of second group 232.Thus, cooling fins of fourth group 234 alternate in vertical direction202 with cooling fins of second group 232, so that each adjustablecooling fin is placed between two corresponding stationary cooling fins.Consequently, the movement in vertical direction 202 of the cooling finsof fourth group 234 can change the effective fin pitch, and thereforethe cooling efficiency, of a center region 239 of heat exchanger 200.

In operation, the cooling efficiency of heat exchanger 200 is adjustedby changing the position of movable support 260 in vertical direction202. For example, to reduce the cooling efficiency of heat exchanger200, movable support 260 is positioned so that the cooling fins offourth group 234, which are coupled to movable support 260, are eachclose to or in contact with a corresponding stationary cooling fin ofsecond group 232. Conversely, as movable support 260 is moved invertical direction 202 so that the cooling fins of fourth group 234 aremoved away from the corresponding stationary cooling fin of second group232, the cooling efficiency of heat exchanger 200 is increased. Oneembodiment of movable support 260 is described below in conjunction withFIG. 3 .

FIG. 3 is a perspective view of movable support 260 disposed within heatexchanger 200, according to various embodiments. In FIG. 3 , movablesupport 260 is installed on a portion of heat pipes 240 of heatexchanger 200. For clarity, first group 231, second group 232, thirdgroup 233, and forth group 234 of cooling fins 221 are omitted in FIG. 3. Movable support 260 is configured to be coupled to a portion of thecooling fins of heat exchanger 200 in FIG. 2 , such as fourth group 234.In addition, movable support 260 is configured to enable movement ofthat portion of the cooling fins of heat exchanger 200 in verticaldirection 202. Because that portion of the cooling fins (e.q., fourthgroup 234) of heat exchanger 200 are all coupled to movable support 260,each of the cooling fins in that portion moves simultaneously invertical direction 202 when movable support 260 is moved in verticaldirection 202.

In the embodiment illustrated in FIG. 3 , movable support 260 includesone or more columns 361 that are each mounted on or coupled to abaseplate 362. Each column is configured to fit around and slide alongan axis 342 of a respective condenser portion 242 of a heat pipe 240.Thus, as baseplate 362 is actuated along vertical direction 202, the oneor more columns 361 and the portion of the cooling fins that are coupledthereto move simultaneously in vertical direction 202. In someembodiments, columns 361 of movable support 260 are configured with oneor more alignment features 364 that mate with a corresponding feature inthe cooling fins of fourth group 234. Additionally or alternatively, insome embodiments, condenser portions 242 of heat pipes 240 areconfigured with one or more alignment features 342 that mate with acorresponding feature in the cooling fins of first group 231, secondgroup 232, and/or third group 233.

Movable support 260 is further configured to be in thermal contact withone or more of condenser portions 242. Specifically, each column 361 isin thermal contact with a corresponding condenser portion 242, therebyfacilitating heat transfer into each column 361 from the correspondingcondenser portion 242. In some embodiments, thermal contact is enhancedbetween each column 361 and the corresponding condenser portion 242 viaa thermally conductive material 363 that is disposed between each column361 and corresponding condenser portion 242. In such embodiments, thethermally conductive material 363 may be selected to further act as alubricant that facilitates relative motion between each column 361 andcorresponding condenser portion 242. Examples of a material suitable foruse as thermally conductive material 363 include graphite-based thermalpaste, some other graphite-based material, or a thermal grease. In FIG.3 , only a visible portion of thermally conductive material 363 disposedon a surface of condenser portion 242 is shown (indicated bycross-hatching).

For causing motion of movable support 260 in vertical direction 202,movable support 260 is coupled to one or more actuators 310. In someembodiments, the one or more actuators 310 are disposed between movablesupport 260 and metallic plate 250 or within metallic plate 250. Inother embodiments, the one or more actuators 310 may be placed in adifferent position on or within heat exchanger 200. The one or moreactuators 310 can be any technically feasible actuators, includingmechanical actuators, thermal actuators, electromechanical actuators, orthe like.

In some embodiments, the one or more actuators 310 are configured tomove movable support 260 to a set position relative to IC 201 and/or tothe one or more condenser portions 242. For example, in one suchembodiment, actuator 310 is a screw-based or other mechanical actuatorthat can be adjusted to a specific position manually during assemblyand/or manufacturing of heat exchanger 200. In such embodiments, heatexchanger 200 can be changed from an upstream heat exchangerconfiguration to a downstream heat exchanger configuration (or viceversa), depending on the targeted application of heat exchanger 200. Onesuch embodiment is illustrated in FIGS. 4A and 4B.

FIG. 4A is an end view of heat exchanger 200 in an upstream heatexchanger configuration, according to various embodiments, and FIG. 4Bis an end view of heat exchanger 200 in a downstream heat exchangerconfiguration, according to various embodiments. As shown in FIG. 4A,heat exchanger 200 is configured to be in an upstream heat exchangerconfiguration, in which cooling fins coupled to movable support 260 areadjusted to each be in contact with one of the stationary cooling finsof heat exchanger 200. When the cooling fins coupled to movable support260 are so adjusted, the effective fin pitch of center region 239 isincreased to that of fixed fin pitch 232A, thereby removing the addedcooling capability associated with the cooling fins of group 234 thatare coupled to movable support 260. Conversely, in FIG. 4B, heatexchanger 200 is configured to be in a downstream heat exchangerconfiguration, in which cooling fins coupled to movable support 260 areadjusted to each be disposed at a specified position relative to thestationary cooling fins of heat exchanger 200. For example, in theembodiment illustrated in FIG. 4B, the specified position for eachcooling fin coupled to movable support 260 is a position that isequidistant from the two adjacent stationary cooling fins of secondgroup 232.

Returning to FIG. 3 , in some embodiments, the one or more actuators 310are configured to move movable support 260 to a set position relative toIC 201 and/or to the one or more condenser portions 242 as a function ofa temperature associated with IC 201. In such embodiments, as thetemperature associated with IC 201 changes, the one or more actuators310 adjust the position of movable support 260 accordingly. Thus, incontrast to the embodiment illustrated in FIGS. 4A and 4B, the one ormore actuators 310 are configured to adjust the position of movablesupport 260 in vertical direction 202 across a continuum of locations.

In some embodiments, the one or more actuators 310 include athermomechanical actuator that generates motion of the first movablesupport in response to a change of the temperature associated with IC201. Examples of thermomechanical actuators suitable for use as anactuator 310 include a bimetallic strip or other member that changesshape with temperature and a wax-based thermal actuator (such as adiaphragm- or piston-type thermal actuator). In wax-based thermalactuator, an actuator 310 includes a thermally actuated mechanism, suchas a reservoir of wax, that expands when heated and contracts whencooled. As a temperature of the reservoir of wax changes, a pistonattached to the reservoir and to movable support 260 moves along aparticular axis of linear motion, such as vertical direction 202. Inthis way, an actuator 310 moves movable support 260 in response to achange in a temperature of the reservoir of wax, which is caused by achange in temperature of IC 201. Thus, the actuator 310 implements athermally controlled movement based on the temperature of IC 201.

In some embodiments, the one or more actuators 310 include anelectronically controlled actuator, such as an electric motor coupledand a controller that controls the electric motor. In such embodiments,the electric motor is coupled to a mechanical actuator, such as apiston, that is attached to movable support 260. In response toreceiving a signal indicating a temperature associated with IC 201, thecontroller causes the actuator to move movable support 260 in verticaldirection 202. In such embodiments, the signal indicating thetemperature associated with IC 201 may be generated by IC 201 itself orby a temperature sensor included in or proximate to adjustable heat sink220. In some embodiments, multiple inputs may be employed to generatethe signal indicating the temperature associated with IC 201, such as aprocessor temperature and a fan speed. In such embodiments, a suitablealgorithm based on the multiple inputs and/or the signal indicating thetemperature associated with IC 201 can be employed by the controller todetermine an amount of actuation of the electric motor.

In some embodiments, the controller for the one or more actuators 310can be integrated in the one or more actuators 310, included in heatexchanger 200, or implemented as one of electronic components 104 (shownin FIG. 1 ) mounted on PCB 102. In some embodiments, the controller forthe one or more actuators 310 can be configured to control similaractuators included in other similar heat exchangers included in the samecomputer system. For example, in one such embodiment, the controller cancontrol the one or more actuators for each of upstream heat exchangers103A and downstream heat exchangers 103B in computer system 100 of FIG.1 .

Cooling Fins for Adjustable Heat Sink

FIGS. 5A - 5C illustrate various cooling fins 221 included in adjustableheat sink 220, according to various embodiments. FIG. 5A shows arepresentative cooling fin 531 that is included in first group 231 andsecond group 232 of cooling fins 221, FIG. 5B shows a representativecooling fin 533 that is included in third group 233 of cooling fins 221,and FIG. 5C shows a representative cooling fin 534 that is included infourth group 234 of cooling fins 221. For reference, the locations ofcondenser portions 242, alignment features 342, columns 361, andalignment features 364 are indicated in FIGS. 5A - 5C as dashed lines.

As shown in FIG. 5A, representative cooling fin 531 generally hasopenings 501 configured to allow movement of columns 361 relative torepresentative cooling fin 531. Representative cooling fin 531 furtherincludes openings 502 configured to mechanically couple representativecooling fin 531 to one or more condenser portions 242 whenrepresentative cooling fin 531 is installed in heat exchanger 200. Forexample, each opening 502 may be configured to couple to a condenserportion 242 and an alignment feature 342 formed thereon. In theembodiment illustrated in FIG. 5A, representative cooling fin 531extends from a first cooling air receiving edge 511 to a second airreceiving edge 512. That is, to maximize or otherwise increase the heattransfer capacity of representative cooling fin 531, representativecooling fin 531 is mechanically coupled to all of heat pipes 240 of heatexchanger 200 and has a surface area that is as large as practicable. Asa result, representative cooling fin 531 has a greater surface area thanrepresentative cooling fin 534.

As shown in FIG. 5B, representative cooling fin 533 generally hasopenings 502 configured to mechanically couple representative coolingfin 533 to one or more condenser portions 242 when representativecooling fin 531 is installed in heat exchanger 200. For example, eachopening 502 may be configured to couple to a condenser portion 242 andan alignment feature 342 formed thereon. In the embodiment illustratedin FIG. 5B, representative cooling fin 533 extends from first coolingair receiving edge 511 to second air receiving edge 512, and thereforehas a greater surface area than representative cooling fin 534.

As shown in FIG. 5C, representative cooling fin 534 generally hasopenings 503 configured to allow movement of condenser portions 242relative to representative cooling fin 534. Representative cooling fin534 further includes openings 504 configured to mechanically couplerepresentative cooling fin 532 to one or more columns 361 whenrepresentative cooling fin 534 is installed in heat exchanger 200. Forexample, each opening 504 may be configured to couple to a column 361and an alignment feature 364 formed thereon. In the embodimentillustrated in FIG. 5C, representative cooling fin 534 has a smallersurface area than representative cooling fin 531. In other embodiments,representative cooling fin 533 has a similar surface area torepresentative cooling fin 531, and extends from first cooling airreceiving edge 511 to second air receiving edge 512.

FIG. 6 is a perspective view of heat exchanger 200 when partiallyassembled, according to various embodiments. In FIG. 6 , the coolingfins 221 of first group 231 and one of the adjustable cooling fins 221of fourth group 234 are installed in heat exchanger 200. In theembodiment illustrated in FIG. 6 , the placement order in center region239 of heat exchanger 200 alternates between adjustable cooling fins 221of fourth group 234 and stationary cooling fins of second group 232.

In the embodiments described above in conjunction with FIGS. 1 - 6 , asingle group of adjustable cooling fins can be repositioned via amovable support. In other embodiments, an adjustable heat sink includesmultiple groups of adjustable cooling fins, where each group ofadjustable cooling fins is mechanically coupled to a different movablesupport. One such embodiment is described below in conjunction with FIG.7 .

FIG. 7 illustrates various cooling fins 221 that are each included in adifferent group of adjustable cooling fins of an adjustable heat sink700, according to various embodiments. FIG. 7 shows a representativecooling fin 731 that is included in a first group of adjustable coolingfins, a representative cooling fin 732 that is included in a secondgroup of adjustable cooling fins, and a representative cooling fin 733that is included in a third group of adjustable cooling fins. Forreference, the locations of condenser portions 242 and columns 761, 771,and 781, are indicated in FIG. 7 as dashed lines. In addition,adjustable heat sink 700 includes a first movable support 760(mechanically coupled to representative cooling fin 731), a secondmovable support 770 (mechanically coupled to representative cooling fin732), and a third movable support 780 (mechanically coupled torepresentative cooling fin 733).

Representative cooling fins 731 - 733 each include openings 705configured to allow movement of representative cooling fins 731 - 733relative to condenser portions 242. Representative cooling fin 731further includes openings 701 configured to mechanically couplerepresentative cooling fin 731 to one or more columns 761 of firstmovable support 760 when representative cooling fin 731 is installed inadjustable heat sink 700. Similarly, representative cooling fin 732further includes openings 702 configured to mechanically couplerepresentative cooling fin 732 to one or more columns 771 of secondmovable support 770 when representative cooling fin 732 is installed inadjustable heat sink 700, and representative cooling fin 733 furtherincludes openings 703 configured to mechanically couple representativecooling fin 733 to one or more columns 781 of third movable support 780when representative cooling fin 733 is installed in adjustable heat sink700.

Similar to movable support 260 in FIG. 2 , first movable support 760 iscoupled to one or more actuators 310, second movable support 770 iscoupled to one or more actuators 310, and third movable support 780 iscoupled to one or more actuators 310. As a result, first movable support760, second movable support 770, and third movable support 780 can eachbe independently moved relative to condenser portions 242, for exampleas a function of a temperature associated with an IC coupled toadjustable heat sink 700. Thus, in the embodiment illustrated in FIG. 7, the group of cooling fins that includes representative cooling fin 731can be repositioned independently from the group of cooling fins thatincludes representative cooling fin 732 and from the group of coolingfins that includes representative cooling fin 733. As a result, one ormore actuators 310 can be configured to move first movable support 760and the group of cooling fins that includes representative cooling fin731 when a temperature is within a first temperature range, one or moreactuators 310 can be configured to move second movable support 770 andthe group of cooling fins that includes representative cooling fin 732when the temperature is within a second temperature range, and one ormore actuators 310 can be configured to move third movable support 780and the group of cooling fins that includes representative cooling fin733 when the temperature is within a third temperature range.

In some embodiments, the first, second, and third temperature ranges canbe overlapping temperature ranges or non-overlapping temperature ranges.In either case, when a heat exchanger includes multiple movable supportsthat can each be independently moved, the cooling efficiency ofadjustable heat sink 700 can be varied continuously over multipletemperature ranges.

Controlling an Adjustable Heat Sink

FIG. 8 is a flowchart of method steps for controlling cooling efficiencyin an adjustable heat sink, according to various embodiments. Althoughthe method steps are described in conjunction with the systems of FIGS.1 - 7 , persons skilled in the art will understand that any systemconfigured to perform the method steps, in any order, is within thescope of the present invention.

As shown, a method 800 begins at step 801, where a suitable controllerreceives one or more signals indicating a temperature associated with IC201. In some embodiments, at least one such signal is generated by IC201 itself. Alternatively, in some embodiments at least one such signalis generated by a temperature sensor included in or proximate to heatsink 201. In some embodiments, at least one such signal is generated bya component of computer system 100, such as a fan that generates a fanspeed signal, a temperature sensor that measures a temperature of aportion of computer system 100 proximate IC 201, and/or a heat exchangerthat is upstream or downstream of IC 201.

In step 802, the controller determines a heat sink adjustment to bemade, if any, based on the one or more signals received in step 801. Insome embodiments, the heat sink adjustment is determined based on asignal indicating a temperature of IC 201. Additionally oralternatively, in some embodiments the heat sink adjustment isdetermined based on a signal indicating a temperature associated with aheat exchanger that is upstream or downstream of IC 201. For example, inone such embodiment, when a downstream heat exchanger (or IC associatedwith the downstream heat exchanger) exceeds a threshold temperaturevalue, the controller determines a heat sink adjustment to adjustableheat sink 220 that reduces the cooling efficiency of heat sink 220,reduces the temperature of cooling air exiting heat sink 220, andincreases the heat transfer capability of the downstream heat exchanger.

Additionally or alternatively, in some embodiments the heat sinkadjustment is determined based on multiple signals that each indicate orare associated with a temperature of a different IC than IC 201. Forexample, in one such embodiment, the controller determines a heat sinkadjustment to adjustable heat sink 220 based on a first temperature ofor associated with IC 201, a second temperature of or associated with aheat exchanger in computer system 100 that is upstream of IC 201, and/ora third temperature of or associated with a heat exchanger in computersystem 100 that is downstream of IC 201.

In some embodiments, the controller controls the adjustment of multipleadjustable heat exchangers 220 included in computer system 100. In suchembodiments, in step 802 the controller also determines in whichadjustable heat sink 220 the adjustment is to be made, if any.

In step 803, in response to the signal received in step 801 and/or tothe heat sink adjustment determined in step 802, the controller causesone or more actuators 310 to move a movable support, e.g., movablesupport 260, relative to condenser portions 242 and/or IC 201. In thisway, the cooling efficiency of one or more adjustable heat sinks ismodified in response to a temperature change in one or more ICs includedin computer system 100.

In sum, the various embodiments shown and provided herein set forth anadjustable heat sink for an integrated circuit. The adjustable heat sinkis configured with one or more groups of movable cooling fins that, whenmoved relative to stationary cooling fins included in the adjustableheat sink, modify the effective cooling efficiency of the adjustableheat sink. Because the cooling efficiency of the adjustable heat sink isnot fixed, the same heat sink can be employed in an upstream heatexchanger and a downstream heat exchanger. Further, in some embodiments,the adjustable heat sink is configured with a controllable actuator thatenables dynamic control of the cooling efficiency of the adjustable heatsink.

At least one technical advantage of the disclosed approach relative tothe prior art is that the disclosed approach results in more efficientcooling of an electronic device that is disposed within a computersystem downstream of an adjustable heat sink. More specifically, whenthe adjustable heat sink is coupled to an upstream electronic devicewithin the computer system, the cooling efficiency of the adjustableheat sink can be reduced, causing the temperature of cooling air exitingthe adjustable heat sink to decrease. As that relatively cooler airpasses over a downstream electronic device within the computer system,the downstream device is cooled relatively more effectively. Thus, theadjustable heat sink can selectively modify the efficiency of cooling ofthe upstream electronic device relative to that of the downstreamelectronic device. Since the adjustable heat sink can be employed in acomputer system as both an upstream heat sink and as a downstream heatsink, the manufacturing process for the computer system is simplified.Further, in operation, the adjustable heat sink provides flexibility inthe placement or orientation within a computer system of a processorboard that includes upstream and downstream heat-generating electronicdevices. These technical advantages provide one or more technologicaladvancements over prior art approaches.

1. In some embodiments, an apparatus comprises at least one heat pipethat is adapted to be thermally coupled to an integrated circuit and hasan evaporator portion and a first condenser portion, wherein the firstcondenser portion extends away from the evaporator portion; a firstplurality of cooling fins that is attached to the first condenserportion; a first movable support that is thermally coupled to the firstcondenser portion and is configured to move a second plurality ofcooling fins relative to the first plurality of cooling fins; and thesecond plurality of cooling fins, which is attached to the first movablesupport.

2. The apparatus of clause 1, wherein the first movable support isconfigured to slide along an axis of the at least one heat pipe to movethe second plurality of cooling fins relative to the first plurality ofcooling fins.

3. The apparatus of clause 1 or 2, wherein the first movable support isconfigured to move a cooling fin in the second plurality of cooling finsfrom a first position between two cooling fins in the first plurality ofcooling fins to a second position between the two cooling fins in thefirst plurality of cooling fins.

4. The apparatus of any of clauses 1-3, wherein the first movablesupport is configured to simultaneously move each cooling fin in thesecond plurality of cooling fins from a respective first position to arespective second position.

5. The apparatus of any of clauses 1-4, wherein each cooling fin in thefirst plurality of cooling fins has a first shape, each cooling fin inthe second plurality of cooling fins has a second shape, and the firstshape is different than the second shape.

6. The apparatus of any of clauses 1-5, wherein the first shape has alarger surface area than the second shape.

7. The apparatus of any of clauses 1-6, further comprising an actuatorconfigured to move the first movable support relative to the firstcondenser portion.

8. The apparatus of any of clauses 1-7, wherein the actuator isconfigured to move the first movable support to a set position relativeto the first condenser portion.

9. The apparatus of any of clauses 1-8, wherein the actuator isconfigured to move the first movable support relative to the firstcondenser portion based on a temperature associated with the integratedcircuit.

10. The apparatus of any of clauses 1-9, wherein the actuator comprisesa thermomechanical actuator that moves the first movable support inresponse to a change of the temperature.

11. The apparatus of any of clauses 1-10, further comprising acontroller configured to receive a signal indicating a temperatureassociated with the integrated circuit, and, in response to the signal,cause an actuator to move the first movable support relative to thefirst condenser portion.

12. The apparatus of any of clauses 1-11, wherein the signal isgenerated by one of the integrated circuit or a temperature sensorincluded within an electronic device along with the integrated circuit.

13. The apparatus of any of clauses 1-12, further comprising: a thirdplurality of cooling fins; and a second movable support that ismechanically coupled to the third plurality of cooling fans andthermally coupled to a second condenser portion of a heat pipe of theheat exchanger and is configured to move the third plurality of coolingfins relative to the first plurality of cooling fins.

14. The apparatus of any of clauses 1-13, further comprising a firstactuator configured to move the first movable support relative to thefirst condenser portion, and a second actuator configured to move thesecond movable support relative to the second condenser portion.

15. The apparatus of any of clauses 1-14, wherein first the actuator isconfigured to move the first movable support relative to the firstcondenser portion based on a temperature associated with the integratedcircuit and the second actuator is configured to move the second movablesupport relative to the second condenser portion based on thetemperature.

16. The apparatus of any of clauses 1-15, wherein the first the actuatoris configured to move the first movable support relative to the firstcondenser portion when the temperature is within a first temperaturerange, and the second actuator is configured to move the second movablesupport relative to the second condenser portion when the temperature iswithin a second temperature range.

17. In some embodiments, a method of controlling an adjustable heat sinkcomprises: receiving one or more signals indicating a temperatureassociated with a first integrated circuit; based on the one or moresignals, determining a heat sink adjustment to be made; and causing anactuator to perform the heat sink adjustment.

18. The method of clause 17, wherein causing the actuator to perform theheat sink adjustment comprises causing the actuator to move a movablesupport that is mechanically coupled to a first plurality cooling finsin the adjustable heat sink relative to a second plurality of fins inthe adjustable heat sink.

19. The method of clause 17 or 18, wherein the adjustable heat sink isthermally coupled to a second integrated circuit that is upstream of thefirst integrated circuit when a computing device that includes the firstintegrated circuit and the second integrated circuit is in operation.

20. In some embodiments, a computer system comprises: a first integratedcircuit; a second integrated circuit that is disposed downstreamrelative to the first integrated circuit with respect to a coolingairflow when the computing system is in operation; and an adjustableheat exchanger that includes: at least one heat pipe that is adapted tobe thermally coupled to the first integrated circuit and has anevaporator portion and a condenser portion, wherein the condenserportion extends away from the evaporator portion; a first plurality ofcooling fins that is attached to the condenser portion; a secondplurality of cooling fins; and a first movable support that ismechanically coupled to the second plurality of cooling fins andthermally coupled to the condenser portion and is configured to move thesecond plurality of cooling fins relative to the first plurality ofcooling fins.

Any and all combinations of any of the claim elements recited in any ofthe claims and/or any elements described in this application, in anyfashion, fall within the contemplated scope of the present invention andprotection.

The descriptions of the various embodiments have been presented forpurposes of illustration, but are not intended to be exhaustive orlimited to the embodiments disclosed. Many modifications and variationswill be apparent to those of ordinary skill in the art without departingfrom the scope and spirit of the described embodiments.

While the preceding is directed to embodiments of the presentdisclosure, other and further embodiments of the disclosure may bedevised without departing from the basic scope thereof, and the scopethereof is determined by the claims that follow.

What is claimed is:
 1. A method of controlling an adjustable heat sink,the method comprising: receiving one or more signals that indicate atleast one temperature associated with at least one aspect of a computersystem in which the adjustable heat sink resides; based on the one ormore signals, determining an adjustment to be made to the adjustableheat sink; and causing an actuator to perform the adjustment.
 2. Themethod of claim 1, wherein causing the actuator to perform theadjustment comprises causing the actuator to move a movable support thatis mechanically coupled to a first plurality cooling fins included inthe adjustable heat sink relative to a second plurality of fins includedin the adjustable heat sink.
 3. The method of claim 1, wherein theadjustable heat sink is thermally coupled to a first integrated circuitthat resides upstream of a second integrated circuit within the computersystem, wherein both the first integrated circuit and the secondintegrated circuit reside within the computer system.
 4. The method ofclaim 1, wherein at least one of the one or more signals is generated bya first integrated circuit that resides within the computer system. 5.The method of claim 1, wherein at least one of the one or more signalsis generated by temperature sensor that resides within the computersystem.
 6. The method of claim 1, wherein at least one of the one ormore signals is generated by at least one of a fan that resides withinthe computer system and generates a fan speed signal, a temperaturesensor that resides within the computer system and measures atemperature of a portion of the computer system proximate to a firstintegrated circuit, or a heat exchanger that resides upstream ordownstream of the first integrated circuit withing the computer system.7. The method of claim 1, wherein at least one of the one or moresignals indicates a temperature associated with a heat exchanger thatresides upstream or downstream of a first integrated circuit within thecomputer system.
 8. The method of claim 7, wherein the heat exchangerresides downstream of the first integrated circuit, and the temperatureassociated with the heat exchanger exceeds a threshold value, and theadjustment reduces a cooling efficiency associated with the adjustableheat sink.
 9. The method of claim 1, wherein at least one of the one ormore signals indicates at least one of a first temperature associatedwith a first integrated circuit that resides within the computer system,a second temperature associated with a heat exchanger that residesupstream of the first integrated circuit within the computer system, ora third temperature associated with a heat exchange that residesdownstream of the first integrated circuit within the computer system.10. A computer system, comprising: a first integrated circuit; a secondintegrated circuit that is disposed downstream relative to the firstintegrated circuit with respect to a cooling airflow when the computingsystem is in operation; an adjustable heat exchanger that includes: atleast one heat pipe that is adapted to be thermally coupled to the firstintegrated circuit and has an evaporator portion and a condenserportion, wherein the condenser portion extends away from the evaporatorportion; a first plurality of cooling fins that is attached to thecondenser portion; a second plurality of cooling fins; and a firstmovable support that is mechanically coupled to the second plurality ofcooling fins and thermally coupled to the condenser portion and isconfigured to move the second plurality of cooling fins relative to thefirst plurality of cooling fins; and a controller that receives one ormore signals that indicate at least one temperature associated with atleast one aspect of the computer system, determines an adjustment to bemade to the adjustable heat sink based on the one or more signals, andcauses an actuator to move the first movable support in order to performthe adjustment.
 11. The computer system of claim 10, wherein theactuator moves the first movable support relative to the first condenserportion.
 12. The computer system of claim 11, wherein the actuator movesthe first movable support to a set position relative to the firstcondenser portion.
 13. The computer system of claim 10, wherein theactuator moves the first movable support relative to the first condenserportion based on a temperature associated with the first integratedcircuit.
 14. The computer system of claim 13, wherein the actuatorcomprises a thermomechanical actuator that moves the first movablesupport in response to a change of the temperature.
 15. The computersystem of claim 10, wherein the adjustable heat exchanger furtherincludes: a third plurality of cooling fins; and a second movablesupport that is mechanically coupled to the third plurality of coolingfans and thermally coupled to a second condenser portion of a heat pipeof the adjustable heat exchanger and is configured to move the thirdplurality of cooling fins relative to the first plurality of coolingfins.
 16. The computer system of claim 15, further comprising a secondactuator that moves the second movable support relative to the secondcondenser portion.
 17. The computer system of claim 16, wherein theactuator moves the first movable support relative to the first condenserportion based on a temperature associated with the first integratedcircuit, and the second actuator moves the second movable supportrelative to the second condenser portion based on the temperature. 18.The computer system of claim 16, wherein the actuator moves the firstmovable support relative to the first condenser portion when thetemperature is within a first temperature range, and the second actuatormoves the second movable support relative to the second condenserportion when the temperature is within a second temperature range. 19.The computer system of claim 10, wherein each cooling fin in the firstplurality of cooling fins has a first shape, each cooling fin in thesecond plurality of cooling fins has a second shape, and the first shapeis different than the second shape.
 20. The computer system of claim 19,wherein the first shape has a larger surface area than the second shape.